Tafraout Group
Tafraout Group | |
---|---|
Stratigraphic range: Toarcian-Middle Aalenian Polymorphum-Murchisonae | |
Type | Geological formation |
Sub-units |
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Underlies | |
Overlies | |
Area | High Atlas[1][2] |
Thickness | Aprox. 3000 m |
Lithology | |
Primary |
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Location | |
Location | Central High Altas |
Coordinates | 31°30′N 5°34′W / 31.50°N 5.56°W |
Approximate paleocoordinates | 26°36′N 3°24′W / 26.6°N 3.4°W |
Region | High Atlas[3][4] |
Country | Morocco |
Type section | |
Named for | Douar Tafraout near Jbel/Assif Tafraout |
Named by | Abdellah Milhi |
Location | Right side valley of Assif Tafraout flowing in a northerly direction. The village of Tafraout lies about 1 km to the north |
Year defined | 1992 |
Thickness at type section | ~550 m (1,800 ft) |
The Tafraout Group (Also "Tafraoute Group" or Zaouiat Ahançal Group) is a geological group of formations of Toarcian-Aalenian (Lower Jurassic-Middle Jurassic) age in the Azilal, Béni-Mellal, Imilchil, Zaouiat Ahansal, Ouarzazate, Tinerhir and Errachidia areas of the High Atlas of Morocco.[5] The Group represents the remnants of a local massive Siliciclastic-Carbonate platform ("Tafraout Platform"), best assigned to succession W-E of alluvial environment occasionally interrupted by shallow marine incursions (tidal flat setting) and inner platform to open marine settings, and marks a dramatic decrease of the carbonate productivity under increasing terrigenous sedimentation.[6] Fossils include large reef biotas with richness in "lithiotid" bivalves and coral mounts ("Patch reef", Tafraout Formation[7]), but also by remains of vertebrates such as the sauropod Tazoudasaurus and the basal ceratosaur Berberosaurus, along with several undescribed genera.[8] While there have been attributions of its lowermost layers to the Latest Pliensbachian, the current oldest properly measured are part of the Earliest Toarcian regression ("MRST10"), part of the Lower-Middle Palymorphum biozone.[5] This group is composed of the following units, which extend from west to east: the Azilal Formation (continental to subtidal, including its synonyms the "Wazzant Formation" and the "Continental Series of Toundoute"); the Amezraï Formation (intertidal environment); the Aguerd-nˈTazoult Formation (intertidal environment); the Tafraout Formation (deposited in a subtidal to inner platform environment) & the Tagoudite Formation (including the "Tamadout Formation", shallow subtidal to open pelagic).[7] They are connected with the offshore Ait Athmane Formation and the deeper shelf deposits of the Agoudim 1 Formation.[9] Overall, this group represents a mixed carbonate-siliciclastic system of several hundred meters thick, dominated by deposits of shallow marine platforms linked to a nearby hinterland dominated by conglomerates.[10] The strata of the group extend towards the central High Atlas, covering different anticlines and topographic features along the mountain range.[11]
The after-effects of the Toarcian Oceanic Anoxic Event are also very present in the marginal marine strata of the Tafraout Group, with the Toksine Section recording a dramatic collapse on the scale of the Tethys of the neritic carbonate system.[12]
Geology
[edit]The Central High Atlas of Morocco is part of a mountain belt formed by the inversion of a rift from the Triassic-Jurassic periods, due to Cenozoic tectonic activity.[13] The region's structure comes from four main tectonic phases: the pre-rift phase tied to the formation of Pangaea, the syn-rift phase during the Late Permian to Late Triassic, influenced by the opening of the Atlantic Ocean and Tethys Ocean, and the post-rift phase, where Jurassic-Cretaceous carbonate platforms formed.[14][15] The High Atlas has thrust and oblique-slip faults from W-E to NE-SW. It is an intracontinental mountain range resulting from the uplift of a large Mesozoic rift system. Triassic to Cretaceous layers are confined within basins, controlled by extensional rift structures. Sedimentation in these basins varied, with marine shales and limestones in the east and fluvial deposits in the west. Several tectonic events during the Triassic-Jurassic boundary reactivated normal faults, leading to the dominance of marls during the Middle Liassic to Toarcian.[16][17][18]
Description
[edit]Aguerd-nˈTazoult Formation
The Aguerd-n'Tazoult formation represents the most recent marginal marine layers in the Amezraï minibasin, dating from the Upper Toarcian-Aalenian periods. It begins with layers that have many conglomerate lenses and ends with coral patch reefs. Sandstones, oolitic, and biodetritic limestones are also found throughout. Red and green marls appear in several layers.[19] There are sometimes conglomerate lenses with Liassic elements, and ooid limestones and oblique stratification are mostly near the patch reefs. This formation reflects a shift from supratidal to intertidal environments, similar to the underlying Trafraout Formation. Local tectonic activity, mainly due to seismic events in the Tethyan region, influenced the formation, causing erosion of older Paleozoic layers.[20]
Amezraï Formation
This formation, found in the Amezraï minibasin and linked to the Tazoult Ridge, dates to the Earliest Toarcian and is identified by brachiopod fossils. It includes sandstones, marls, and biodetrital or oolitic limestones, with layers varying from centimeters to up to 6 meters thick. The lower part consists of conglomerates, sandstones, and clays, transitioning to limestones and marls at the top.[19] Ripple structures and cross-bedding are common in sandstone layers, while reworked horizons appear in the limestone. The formation reflects a subtidal to supratidal environment, with some layers suggesting lagoonal conditions and reduced carbonate content compared to older formations.[7]
Azilal Formation
These were deposited in an alluvial setting with occasional shallow marine intrusions, indicating a significant sea level drop after the Lower Toarcian.[2][21] At the "Tarhia n’Dadès" site, marine layers from the Pliensbachian Choucht Formation are covered by one meter of red silt and limestone, signaling a shift to more land-based environments in the Aganane Formation. The boundary with the Azilal Formation features a weathered surface rich in plant material, indicating land expansion and a reduction in the carbonate platform size.[22] The lithology of the Azilal Formation recovers a Claystone-dominated interval, incised by metric dolomitized beds of Mudstones, Peloid-rich Packstones, Ooid-rich Grainstones, and Polymictic Conglomerates, all rich in Terrestrial plant debris, with faunal content very poor and mostly dominated by microbial facies. This unit brings together sandstones, sometimes coarse or conglomeratics, especially red silts and some irregularly bedding carbonate horizons (lacustrine limestones?) as well as rarer coal beds.[2]
The base of the East Azilal Formation transitions gradually from the Aganane Formation’s limestone to the red pelites of the Azilal Formation.[2] The upper limit connects to Bin-el-Ouidane limestones, marked by the first appearance of massive limestones with “bird’s eye” patterns. To the west, it rests smoothly on either the Aït-Bazzi Formation or its equivalent, Aganane, seen where limestone mixes with red pelites. In some areas, it sits discordantly on older sediments, evident by blunted blocks in conglomerates. The western limit shows greenish clay levels between the red pelites and limestone, gradually transitioning to the Bajocian Tanant Formation.[2]
There is little evidence of volcanic activity during the deposition of the Azilal Formation, and any volcanic rocks found have been reassigned to younger periods. The only possible signs of volcanism are explosive volcanic eruption beds found near Toundoute, possibly linked to early activity along the South-Atlasic Fault, with trachyandesitic materials from explosive sources, similar to older Mouluya outcrops.[23]
Tafraout Formation
The Tafraout Formation consists of oolitic and biodetrital limestones with cross-stratifications, found in channels and bars, alongside greenish marls and micro-conglomerates.[7] These layers were deposited on a coastal platform. The formation is mainly made of sandstones, marls, and ooid limestones, different from older layers. Common fossils include bivalves, brachiopods, gastropods, corals, and echinoderms, with plant remains in some sandstones. The rocks formed in environments ranging from supratidal to subtidal, characterized by tropical conditions akin to those observed on Andros, Bahamas.[24] The upper part of the formation shows sediments filling an old Pliensbachian basin, moving from deeper marine conditions to a supratidal coastal plain. Fossils and sediment features suggest a challenging environment, with alternating sandstone and marl layers indicating changes in water depth and sedimentation patterns.[7]
Tagoudite Formation
The Tagoudite Formation marks a major shift in Liassic sedimentation, replacing the carbonate turbidites of the Ouchbis Formation with mostly siliciclastic layers. These layers alternate between gray and green sandstone, sandy marls, and siltstones, forming sequences up to 20 meters thick.[7] They show a decrease in grain size and an increase in marl content from bottom to top, with features like ripple marks and laminations. Microscopically, the turbidites are mainly fine silt, with varying amounts of quartz, feldspar, and carbonate detritus, and occasional pyrite. This formation suggests an open marine environment with sediment interruptions and materials coming from distant areas. It is widespread in the Central High Atlas, with thicknesses reaching up to 320 meters, and varies across different regions like Tounfite and Beni Mellal. In the Central Middle Atlas, sedimentation was interrupted by emersion before the formation's deposition.[7]
Paleogeography
[edit]The Tafraout Group was formed on the Moroccan Carbonate Platform during a sea-level rise in the Early Toarcian, linked to the Toarcian Oceanic Anoxic Event, at a palaeolatitude between 19°-20°N, around the same latitude as modern Mauritania or Cuba, situated between ancient geological regions like the West Moroccan Arch, the Anti-Atlas and the Sahara craton, developed after a major sea regression, with red clays and conglomerates filling small basins in the Atlas region.[25][26]
Two main stages mark the area's evolution: during the Lower Toarcian, deposition patterns from the earlier Pliensbachian continued, followed by terrigenous materials filling the basins and stopping temporally the carbonate production.[5] It evolved along several depocenters and associated accidents, the southern edge of the Tilougguit Syncline in the north to the axis of the Aït Bouguemmez Basin in the south, showed that the depocenter zone corresponded to the disposal area located between the Talmest-Tazolt Ridge to the North and the North-Atlasic accident to the South. This terrestrial lithology is mostly found in the small basins in tearing in the Atlas of Telouet, Toundoute, Afourer and Azilal, having the Demnat Accident as the major structural element in this last sector. While at this W areas it becames fully terrestrial/intertidal, at other areas like Beni Mellal, Dadès Gorges or Zaouiat Ahansal marine influences are seen in a carbonate-siliclastic regime.[24] By the Middle Toarcian-Aalenian, the Azilal Formation expanded eastward, with isolated carbonates of Aguerd-nˈTazoult Formation forming in the Amezraï basin, surrounded by terrigenous sediments.[5][24] This period is marked by the individualization of thein the center of the basin and by a relative tectonic calm in the other coeval sectors.[24]
Marine fossils like brachiopods and ammonites help date the sediment layers and confirm the transition from marine to expansive E terrestrial environments during the Middle Toarcian. The deposition starts with a marked break of the Carbonate production and a major regression in the Lowermost Toarcian, then oscilated Transgresive/Regresive cycles in the Laevisoni-Bifrons substages, followed finally by a post Bifrons major regression and full return to the Carbonate production.[5][26] The Tafraout Platform deepened over time, signaling a shift to transgressive conditions even with the expansion of W continental facies.[24] On the Amezraï Formation basin the fauna is composed by brachiopods such as Soaresirhynchia bouchardi, S. babtisrensis and Pseudogibbirhynchia jurensis that corroborate the Earliest Toarcian age for it and adjacent layers.[24] Meanwhile, the presence of Aalenian (Bradfordernsis-Murchinsonae) Branchiopods in the Aguerd n’Tazoult Formation coeval with Ammonites of the same age in the easternmost Azilal formation at the Ikerzi Area confirms the marine delimitation in the last stages of deposition.[7] In the Azilal-Aguerd system, the "Tafraout Platform" saw a deepening towards the uppermost layers, teasing the transition to the Bin El Ouidane transgressive Carbonate Platform facies, while the lower sequences, with fine conglomerate layers and plant remains indicate a proximal delivery area and the peak of the regression, with many microlagoons that formed between the large coral patch reefs are documented by micrite and partially leached micrite.[7]
Paleoenvironment
[edit]The Tafraout Group covers most of the W High Atlas, surrounded by highlands that probably hosted dry cool (10.6 °C) to humid climate (12.30 °C), with a succession rain tundra to wet forest environments, as proven by samples from coeval layers in the External Rif Chain.[27] The Continental/Tidal Flat Azilal & Aguerd n’Tazoult Formation, within this group, was deposited in coastal environments influenced by rivers, tidal flats, and paralic settings, rwith eworked material and in Toundoute unique interbedded Explosive eruption-type volcanic material, generally constituting more than half of the detrital components, showing clear carbonate recrystallization, suggesting that these fragments were still at high temperature during deposition and, therefore, contemporaneous with the sedimentation, probably as a result of early activity in the local South-Atlasic Fault.[23] Fauna, including rare brachiopods and bivalves, alongside sedimentary features like ripple marks and rain imprints, indicate a mix of marine and continental conditions, with evidence of emersions. The environment shifted from coastal facies in the north to fluvial facies in the south, and tectonic activity affected sediment deposition.[26][24] The flow of the fluvial-washed sediments take place in a E-NE direction, being moved to the layers of the Amezräi, Tagoudite & Tafraout Formations and other coeval marine units, as well are found on fluviatile channels inside the own rocks of this unit.[5]
The Azilal/Aguerd n’Tazoult Formation also saw high plant activity, with remains such as wood, charcoal, and rhizoliths, indicating nearby vegetated soils.[28] Fluvial systems transported sediment from Paleozoic and Triassic sources, with volcanic material also present, suggesting active volcanic processes during deposition.[23] The warm, alternating wet and dry climate led to the formation of soils with calcareous nodules and gypsum in arid zones, particularly in areas like Toundoute and Telouet.[23]
During the Lower Toarcian, a shift to siliciclastic deposits occurred, marked by storm events and increased plant debris, indicating a warm, humid climate.[26] Some areas, especially near the coast, resembled modern Sabkha (like those in the Persian Gulf). The Tafraout Formation, meanwhile, represented marginal marine environments with diverse marine fauna, including coral reefs and "lithiotid" (Plicatostylidae aberrant reef-forming) bivalves.[29]
The Toarcian Oceanic Anoxic Event (T-OAE) intensified Tropical storms, destroying older carbonate platforms and increasing siliciclastic deposits, which contributed to the formation of the Tafrout environment.[30][31] Additionally, after the T-OAE, ecosystems in areas like Jebel Toksine began to recover with new carbonate activity and diverse marine life, including bivalves and other reef organisms.[5][12]
The aftermath of the T-OAE is visible in the lower Azilal Formation, showing a slow recovery of marine environments. There is also evidence of a Middle Toarcian cold snap, followed by a return to warmer conditions.[32] The eastern and northeastern High Atlas saw the development of carbonate sedimentation, with reefs and marine fossils indicating tectonic activity during the Late Toarcian.[5][32]
The central High Atlas region features long diapirs and minibasins formed during early Jurassic rifting, with the Tazoult Ridge being a key example.[33] Diapir movement shaped the surrounding rock layers, while local sedimentation reflects changes in climate, including wetter periods linked to increased erosion. Sharp geological boundaries mark the closure of salt walls during diapir growth, and ancient environments here resembled modern shallow waters like the Red Sea.[34] Charcoal remnants suggest coastal forests or mangroves existed during wetter times.[35]
Biota
[edit]Foraminifera
Genus | Species | Location | Formation & Age | Material | Habitat | Notes | Images |
---|---|---|---|---|---|---|---|
Ammobaculites[10] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Ammomarginulininae. | |
Dentalina[10] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Nodosariinae. | |
Everticyclammina[10] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the Everticyclamminidae family. It represents a species related to E. virguliana, known from the Middle Jurassic of Morocco | |
Citharina[24] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Vaginulininae. It represents a species related to E. virguliana, known from the Middle Jurassic of Morocco | |
Glomospira[36] |
|
|
|
Calcareous Skeleton | Shoreface to Open Marine | A foraminifer of the family Ammodiscidae. | |
Glomospirella[36] |
|
|
|
Calcareous Skeleton | Shoreface Marine | A foraminifer of the family Ammovertellininae. | |
Haurania[36] |
|
|
|
Calcareous Skeleton | Shoreface Marine | A foraminifer of the family Hauraniinae. | |
Ichtyolaria[10] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Ichthyolariinae. | |
Lenticulina[24][37] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | Un foraminifère de la famille des Lenticulininae. | |
Lingulina[24] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Lenticulininae. | |
Marginulina[24] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Marginulininae. | |
Nodosaria[24][36][37] |
|
|
|
Calcareous Skeleton | Shoreface to Open Marine | A foraminifer of the family Nodosariinae. | |
Ophtalmidium[24][36][37] |
|
|
|
Calcareous Skeleton | Shoreface to Open Marine | A foraminifer of the family Ophthalmidiidae. | |
Orbitopsella[38] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Orbitopsellinae. | |
Pseudocyclammina[10] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Hauraniidae. | |
Placopsilina[36] |
|
|
|
Calcareous Skeleton | Open Marine | A foraminifer of the family Placopsilinidae. | |
Pseudonodosaria[24] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Nodosariinae. | |
Reinholdella[10][37] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A foraminifer of the family Ceratobuliminidae. | |
Siphovalvulina[36] |
|
|
|
Calcareous Skeleton | Shoreface to Open Marine | A foraminifer of the family Pseudopfenderininae. | |
Spirillina[37] |
|
|
|
Calcareous Skeleton | Shoreface to Open Marine | A foraminifer of the family Spirillinidae |
Marine Palynomorphs
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Botryococcus[39] |
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|
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Miospores | Member of the family Botryococcaceae inside Trebouxiales. | |
Carinolithus[39] |
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|
|
Calcareous Skeletons | Member of the family Calyculaceae inside Parhabdolithaceae. | |
Luehndea[39] |
|
|
|
Cysts | A Dinoflagellate cyst, type member of Luehndeoideae. Constitutes an excellent marker of
the Pliensbachian-Toarcian interval. |
|
Mancodinium[39] |
|
|
|
Cysts | A Dinoflagellate cyst, type member of Mancodiniaceae. Dominant genera on some layers of the Lias Delta Stage. | |
Mendicodinium[39] |
|
|
|
Cysts | A Dinoflagellate cyst, member of Dinophyceae. | |
|
|
|
Cysts |
A member of Prasinophyceae. The presence of this genus indicates fresh or brackish water inputs in the depositional environment |
"Algae"
Genre | Species | Location | Formation & Age | Material | Habitat | Notes | Images |
---|---|---|---|---|---|---|---|
Cayeuxia[29] |
|
|
|
Calcareous Skeleton | Shallow Marine/Lagoonal | A green algae of the Halimedaceae or Udoteaceae family. |
Invertebrates
[edit]In the Tafraout Group, the fossil record of units like the Azilal Formation is very restrictive compared to the marine coeval/underliying units like the Amezraï or Tafraout Formations. In the Dadés area Coral patch reefs rarely occur in the middle of the unit with associated echinodems (Sea urchin spines, Crinoid fragments) lamellibranchs, gastropods, solitary corals and algae.[7] Plant remains are very abundant in places such as the north of Jbel Akenzoud and partly impregnated and/or carbonized by malachite.[7] Gastropods have been discovered in several places, but none of the specimens have been studied nor identified.[40] Beds with large accumulations of unidentified Ostracod valves on an endemic thin level of green marl are found at the Beni-Mellal area (Adoumaz & Col de Ghnim outcrops).[41][42] The tubes of serpulid worms are known from Jbel Toksine, in relation to the bivalve pavements.[29]
Color key
|
Notes Uncertain or tentative taxa are in small text; |
Ichnofossils
Genus | Species | Location | Formation & Age | Material | Type | Made by | Images |
---|---|---|---|---|---|---|---|
Arenicolites[26][43] |
|
|
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Traces of habitation | Domichnia |
|
|
Chondrites[43] |
|
|
|
Tubular Fodinichnia | Fodinichnia |
|
|
Rhizocorallium[32][43] |
|
|
|
Tubular Fodinichnia | Domichnia or fodinichnia |
|
. |
Scolicia[26] |
|
|
|
Locomotion or feeding trace | Fodinichnia |
|
|
Skolithos[43] |
|
|
|
Cylindrical to subcylindrical burrows | Domichnia |
|
. |
Thalassinoides[26][43] |
|
|
|
Tubular Fodinichnia | Fodinichnia |
|
. |
Zoophycos[26][43] |
|
|
|
Traces of habitation | Domichnia & Fodinichnia |
|
Anthozoa
The platform patch reefs in the Tafraout area are notable for their biodiversity, with some reaching heights of up to 40 m and lengths of up to 80 m, representing massive biostromes with a varied associated fossil assemblage, including bivalves, gastropods, echinoderm fragments, solitary corals, and bryozoans, found among the coral patchs.[7] Massive reef pinnacles are recovered at Anergui and northern flank of Tassent, while rarer ones are know from Bou Zemou.[37]
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Actinaraea?[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Actinacididae. | |
Ampakabastraea[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Stylinidae. | |
Archaeosmilia[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Zardinophyllidae. These solitary corals were observed throughout the lower unit biostromes. | |
Archaeosmiliopsis[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Archaeosmiliidae. | |
Enallhelia?[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Stylinidae. | |
Haimeicyclus[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Oppelismiliidae. | |
Hispaniastraea[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Hispaniastraeidae. | |
Lophelia?[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Carophylliidae. | |
Myriophyllum[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Oppelismiliidae. | |
Phacelostylophyllum[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Stylophyllidae. | |
Phacelophyllia[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Dermosmiliidae. | |
Periseris[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Latomeandridae. | |
Spongiocoenia[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Stylophyllidae. | |
Thecactinastraea[29] |
|
|
|
Calcified Skeletal Pieces | A coral of the family Oppelismiliidae. |
Brachiopoda
Genre | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Curtirhynchia[24] |
|
|
|
Isolated shells | A brackish/marine Tetrarhynchiidae (Brachiopod) | |
Gibbirhynchia[44] |
|
|
|
Isolated shells | A brackish/marine Tetrarhynchiidae (Brachiopod) | |
Globirhynchia[24] |
|
|
|
Isolated shells | A brackish/marine Rhynchonellidae (Brachiopod) | |
Quadratirhynchia[44][45] |
|
|
|
Isolated shells | A brackish/marine Tetrarhynchiidae (Brachiopod) | |
Homoeorhynchia[20][45] |
|
|
|
Isolated shells | A brackish/marine Rhynchonellinae (Brachiopod). Homoeorhynchia meridionalis indicates the Toarcian Serpentinus zone and base of the Bifrons zone | |
Liospiriferina[12] |
|
|
|
Isolated shells | A brackish/marine Spiriferinidae (Brachiopod) | |
Pseudogibbirhynchia[44][46] |
|
|
|
Isolated shells | A brackish/marine Pamirorhynchiinae (Brachiopod). | |
Soaresirhynchia[24][44][45] |
|
|
|
Isolated shells | A brackish/marine Basiliolinae (Brachiopod) | |
Sphaeroidothyris[20] |
|
|
|
Isolated shells | A brackish/marine Lobothyrididae (Brachiopod) | |
Stroudithyris[20][32] |
|
|
|
Isolated shells | A Brackish/marine Lissajousithyrididae (Brachiopod). Mostly benthonic specimens are known. The presence of this species indicates an upper Toarcian-Aalenian age for the layers where was discovered. | |
Telothyris[20][45] |
|
|
|
Isolated shells | A brackish/marine Lobothyrididae (Brachiopod). Relatively abundant on seashore deposits. Includes juvenile forms of Telothyris jauberti, present on benthic deposit strata. |
Bivalves
"Dwarf black bivalves (Lucinidae?)" in great abundance where reported from the Azilal Formation at its type section.[47]
Genre | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Chlamys[48] |
|
|
|
Isolated Shells | A Pectinidan, member of the family Pectinidae | |
Cochlearites[29][49] |
|
|
|
Isolated shells | A brackish/marine Plicatostylidae (Bivalve). A large bivalve, with a subequivalent shell, reaching 60–70 cm high. It is one of the three main bivalves found on the Lithiotis Facies, whose accumulations generally cover megalodontid coquinas. | |
Gervillioperna[29] |
|
|
|
Isolated shells | A brackish/marine Plicatostylidae (Bivalve). Abundant along rootlets, indicating a very shallow and restricted lagoon or marsh environment | |
Lithioperna[29][49] |
|
|
|
Isolated shells | A brackish/marine Plicatostylidae (Bivalve). This genus was founded to be a bivalve with a byssate juvenile stage that developed different lifestyles as adults depending on the density of the individuals and the firmness of the bottom | |
Pachygervillia[29][50] |
|
|
|
Isolated shells | A brackish/marine Plicatostylidae (Bivalve). | |
Opisoma[29][49] |
|
|
|
Isolated shells | A brackish Astartidae (Bivalve). Is considered a genus that evolved from shallow-burrowing ancestors, secondarily becoming an edge-prone semi-fauna adapted to photosymbiosis. | |
Trichites[35] |
|
|
|
Isolated shells | A marine Pinnidae (Bivalve) | |
Pholadomya[35] |
|
|
|
Isolated shells | A marine Pholadomyidae (Bivalve) | |
Spondylus[48] |
|
|
|
Isolated Shells | A marine member of the family Spondylidae |
Gastropoda
Multiple Gasteropodan faunas are know, specially associated with coral patch reefs, but lack proper studies.[7]
Genre | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Nerinea[29] |
|
|
|
Isolated shells | A Nerineoidean, member of the family Nerineidae | |
Neritodomus[51] |
|
|
|
Isolated Shells | A Cycloneritidan, member of the family Neridomidae | |
Platyacra[51] |
|
|
|
Isolated Shells | A Trochoidean, member of the family Angariidae | |
Purpurina[51] |
|
|
|
Isolated Shells | A Caenogastropodan, member of the family Purpurinidae | |
Scurriopsis[29] |
|
|
|
Isolated shells | A Lottioidean, member of the family Acmaeidae |
Ammonites
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Alocolytoceras[37] |
|
|
|
Isolated shells | An Ammonite of the family Lytoceratidae. | |
Calliphylloceras[52] |
|
|
|
Isolated shells | An Ammonite of the family Calliphylloceratinae | |
Canavaria[52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. | |
Dactylioceras[7][24][52] |
|
|
|
Isolated shells | An Ammonite of the family Dactylioceratidae. The basis of this series is based on a regional discontinuity marked by a remarkable abundance of Eodactylites from the Lower Toarcian | |
Eleganticeras[12][52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. | |
Harpoceras[12][52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. | |
Hildaites[52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. | |
Hildoceras[7][24] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. Characteristics of the base of the area in Bifrons | |
Lytoceras[52] |
|
|
|
Isolated shells | An Ammonite of the family Lytoceratidae. | |
Neolioceratoides[52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. | |
Planammatoceras[7] |
|
|
|
Isolated shells | An Ammonite of the family Hammatoceratidae. Indicator of a Middle Aalenian age for the uppermost layers, as is found also on the Middle Atlas. As well evidence of greater marine influx in the easternmost outcrops. | |
Praepolyplectus[52] |
|
|
|
Isolated shells | An Ammonite of the family Hildoceratidae. |
Crustacea
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Polycope[10] |
|
|
|
Isolated Valves | A marine/brackish Polycopidae (Ostracoda). Present with large accumulations of specimens |
Echinodermata
Multiple echinoderm remains, including Crinoid articulated and fragmentary specimens and indeterminate echinoid fragments, are know from several localities, usually associated with large coral bioherms or sea trangressions.[7][10][53][24]
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Arbacioida[29] | Indeterminate |
|
|
Complete specimens and isolated parts of the exoskeleton | A marine Arbacioida (Echinoidean). These sea urchins are the most abundant echinoderms on local lithiolid reefs. | |
Pentacrinites[54] |
|
|
|
Complete specimens and isolated parts of the exoskeleton | A Crinoid of the family Pentacrinitidae |
Vertebrates
[edit]Several scales & teeth of fishes (Lepidotes?) are know from several locations, coming from freshwater/lagoonal layers.[47] Indeterminate dinosaurian & other vertebrates are know from Mizaguène Hill, Taouja Ougourane, Aït Ouaridène, Oued Rzef & Jbel Remuai in the Azilal Province. Some of them are recovered in a "Bone bed" and others are associated with abundant plant remains.[55]
Actinopteri
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Leptolepis[7][10] |
|
|
|
|
Marine, brackish or freshwater bony fish of the family Leptolepidae. Recovered from the Tagoudite Formation, represents a genus of cosmopolitan fish, common in the Toarcian Mediterranean area. Most specimens appear to come from lagoonal facies. |
|
Leptolepididae[7] |
Indeterminate |
|
|
|
Marine or brackish bony fish of the family Leptolepidae. |
Dinosauria
Genus | Species | Stratigraphic position | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Berberosaurus[56] | B. liassicus |
|
Azilal Formation, Toarcian |
|
Described originally as a basal representative of the Abelisauroidea, it was recovered as a basal ceratosaur in later studies. It was a medium-sized theropod, measuring 5.1 m (17 ft) long, with a weight of 200 kg (440 lb). | |
Coelophysidae[58][59][60] | Indeterminate |
|
Azilal Formation, Toarcian | Two adults and one recently hatched juvenile. At least the posterior half of the skeleton is present: caudal, sacral, dorsal vertebrae, pelvis and both hind legs | A coelophysid coelophysoid. According to Mickey Mortimer: "Assigned to Coelophysidae based on the apparent fusion between distal tarsal III and metatarsal III". It has been also proposed as a possible tetanuran.[61] That was dismissed by Benson in 2010.[62] Includes at least three different individuals that have been collected in Wazzant: two adults and a newly hatched juvenile. The former foot material resembles the Cretaceous Australian genus Kakuru, that has been proposed as a basal tyrannoraptoran. Mortimer said that "I really don't see much resemblance to Kakuru in the astragalus" and labeled it as a possible dilophosaurid or coelophysoid.[63] | |
Gravisauria[64][65] | Indeterminate |
|
Azilal Formation, Toarcian | Pubis and other indeterminate remains | A gravisaurian sauropod. Quoted to resemble Tazoudasaurus | |
Eusauropoda[58][60][64] | Indeterminate |
|
Azilal Formation, Toarcian | 5 dorsal & caudal vertebrae, fragmentary ribs, chevrons and several large badly determinable debris.[64][59][66] | A eusauropodan sauropod maybe related with Spinophorosaurus. Was collected on a freshwater lagoonal depositional setting.[64] | |
Large Bodied Theropod[56] | Indeterminate |
|
Azilal Formation, Toarcian | Phalanges and several non mentioned remains.[67] | Described as a "Large theropod of uncertain affinities"[56] and as an "enigmatic theropod".[68] To quote Allain: "Two theropods have been found on Toundoute. The first theropod hasn't been described but shows a size larger than any of the know theropods of the Triassic-Early Jurassic know by now, indicating that Toarcian theropods had sizes rivaling that of late Jurassic allosaurs".[65] | |
Sauropoda[58][59][60] | Indeterminate |
|
Azilal Formation, Toarcian | Left ilium, a humerus and three vertebrae. | A possible basal sauropod of uncertain affinities. Remains recovered represent a Juvenile | |
Sauropodomorpha[58][69] | Indeterminate |
|
Azilal Formation, Toarcian | One or more vertebrae and other unidentified remains | A possible Sauropodomorpha of uncertain affinities. P. Lévêque brought these bones back from a hill which he placed in Cretaceous strata, but more recent work has shown that the deposit is in fact in Toarcian layers. | |
Tazoudasaurus[70] | T. naimi |
|
Azilal Formation, Toarcian | Around 10 different specimens:Partially articulated skeleton and cranial material including complete left mandible with teeth, quadrate, jugal, postorbital, parietal, frontal and exoccipital. Associated remains of a juvenile skeleton. | A gravisaurian sauropod related to Vulcanodon. The most complete sauropod from the Lower Jurassic Found, with adult, sub adult and juvenile specimens.[56][68][67][60] | |
Theropodipedia[1] | Indeterminate |
|
Azilal Formation, Toarcian | Footprints | Small three-toed footprints, likely belonging to Theropods |
Plantae
[edit]The vegetation in the Toundoute area is compared to that of the Isle of Pines.[71] Paleosols in these regions show many plant roots (Rhizoliths) and heavily disturbed layers.[72] Plant remains include coal, leaves, woody roots, rhizoliths, fossil wood, and other plant debris. In Toundoute, small plant fragments, mostly fern leaflets and some cycad leaves, were found, with wood debris resembling conifers like Pinaceae or Taxaceae.[23][73] Ferns seem to have dominated the vegetation, likely in wetlands, followed by cycads and conifers.[23] Similar plants have been found in Egypt's Mashabba Formation.[74] At Jebel Toksine, woody plant debris, including charcoal, suggests vegetation in a humid, marginal marine environment.[29] Jebel Azourki has layers of shales with coal streaks and plant fragments, possibly representing a marsh in a lagoon area.[53]
Palynology
Phytoclasts, spores, pollen and Tasmanites algae indicate that the palaeoenvironment of the lower Toarcian Amellago area was likely proximal continental shelf with a high terrestrial input, and notorious influence of brackish water in the depositional environment.[39]
Genus | Species | Location | Formation & Age | Material | Notes | Images |
---|---|---|---|---|---|---|
Alisporites[39] |
|
|
|
Pollen | Affinities with the families Peltaspermaceae, Corystospermaceae or Umkomasiaceae inside Peltaspermales. | |
Callialasporites[39] |
|
|
|
Pollen | Affinities with Araucariaceae inside Coniferae. | |
Classopollis[39] |
|
|
|
Pollen | Affinities with Cheirolepidiaceae inside Coniferae. This interval is numerically dominated by Classopollis, which usually accounts for more than 60.95% of the palynomorphs present | |
Kraeuselisporites[39] |
|
|
|
Spores | Affinities with Selaginellaceae and probably Lycopsida. Age indicator, also present on nearby regions | |
Ischyosporites[39] |
|
|
|
Spores | Affinities with Incertade sedis Pteridopsida or alternatively with Schizaeaceae/Anemiaceae. | |
Quadraeculina[39] |
|
|
|
Pollen | Affinities with Podocarpaceae or Pinaceae inside Coniferophyta. |
Fossil Wood
At the top of the formation at the Idemrane geosite, unidentified pieces of wood fossils of variable sizes were recovered (largest over 20 cm in length) showing traces of iron oxides. This woody pieces are considered root fragments.[75]
Genus | Species | Stratigraphic position | Formation & Age | Material | Habit | Notes | Images |
---|---|---|---|---|---|---|---|
Metapodocarpoxylon[76][77] |
|
|
Azilal Formation, Toarcian-Aalenian |
|
Arboreal, high canopy, linked with floodplain margins yet high aridity tolerant | Conifer fossil wood related with Podocarpaceae inside Pinales. Probably built evergreen tropophilous forests in alluvial plains together with Agathoxylon. A genus closely related with Dacrydium and Dacrycarpus.[78] |
See also
[edit]- Marne di Monte Serrone, Italy
- Calcare di Sogno, Italy
- Podpeč Limestone, Slovenia
- El Pedregal Formation, Spain
- Cañadón Asfalto Formation, Argentina
- Los Molles Formation, Argentina
- Mawson Formation, Antarctica
- Kandreho Formation, Madagascar
- Kota Formation, India
- Cattamarra Coal Measures, Australia
References
[edit]- ^ a b Jenny, J. (1985). "Carte Géologique du Maroc au 1: 100.000, feuille Azilal". Notes et Mémoires du Service Géologique du Maroc. 339 (2): 1–104. Retrieved 25 January 2022.
- ^ a b c d e Jenny, J. (1988). "Carte géologique du Maroc au 1/100 000: feuille Azilal (Haut Atlas central). Mémoire explicatif". Notes et Mémoires du Service géologique. 378 (1): 1–122. Retrieved 25 January 2022.
- ^ Peleogeographiques, C. E. R. (2002). "Les formations lithostratigraphiques jurassiques du Haut Atlas central (Maroc) : corrélations et reconstitutions paléogéographiques". Documents des laboratoires de géologie Lyon. 156 (1): 163. Retrieved 25 January 2022.
- ^ El Bchari, F.; Ibouh, H.; Souhel, A.; Taj-Eddine, K.; Canérot, J.; Bouabdelli, M. (2001). "Cadre stratigraphique et étapes de structuration de la plate-forme liasique d'Aït Bou Guemmez (Haut-Atlas central, Maroc)". Revista de Geociências. 16 (3): 163–172. Retrieved 25 January 2022.
- ^ a b c d e f g h Krencker, F.-N.; Fantasia, A.; El Ouali, M.; Kabiri, L.; Bodin, S. (2022). "The effects of strong sediment-supply variability on the sequence stratigraphic architecture: Insights from early Toarcian carbonate factory collapses". Marine and Petroleum Geology. 136: 105469. Bibcode:2022MarPG.13605469K. doi:10.1016/j.marpetgeo.2021.105469. ISSN 0264-8172.
- ^ Ettaki, M; Ouahhabi, B.; Dommergues, J. L.; Meister, C.; Chellaï, E. H. (2011). "Analyses biostratigraphiques dans le Lias de la bordure sud de la Téthys méditerranéenne: l'exemple de la frange méridionale du Haut-Atlas central (Maroc)". Bulletin de la Société Géologique de France. 182 (6): 521–532. doi:10.2113/gssgfbull.182.6.521. Retrieved 25 January 2022.
- ^ a b c d e f g h i j k l m n o p q r s Milhi, Abdellah (1992). Stratigraphie, Fazies und Paläogeographie des Jura am Südrand des zentralen Hohen Atlas (Marokko). Selbstverlag Fachbereich Geowissenschaften, FU Berlin. OCLC 763029903.
- ^ Ibrahim, N.; Sereno, P. C.; Zouhri, S.; Zouhri, S. (2017). "Les dinosaures du Maroc–aperçu historique et travaux récents" (PDF). Mémoires de la Société Géologique de France. 180 (4): 249–284. Retrieved 21 April 2023.
- ^ Stüder, M.; du Dresnay, R. (1980). "Deformations synsedimentaires en compression pendant le Lias superieur et le Dogger, au Tizi n'Irhil (Haut Atlas central de Midelt, Maroc)". Bull. Soc. Géol. Fr. 34 (3): 391–397. doi:10.2113/gssgfbull.S7-XXII.3.391. Retrieved 28 March 2022.
- ^ a b c d e f g h i j Ettaki, Mohammed; Chellaï, El Hassane (2005-07-01). "Le Toarcien inférieur du Haut Atlas de Todrha–Dadès (Maroc) : sédimentologie et lithostratigraphie". Comptes Rendus Geoscience. 337 (9): 814–823. Bibcode:2005CRGeo.337..814E. doi:10.1016/j.crte.2005.04.007. ISSN 1631-0713.
- ^ Dresnay, Renaud du (1971-01-01). "Extension et developpement des phenomenes recifaux jurassiques dans le domaine atlasique marocain, particulierement au Lias moyen". Bulletin de la Société Géologique de France. S7-XIII (1–2): 46–56. doi:10.2113/gssgfbull.s7-xiii.1-2.46. ISSN 1777-5817.
- ^ a b c d e Bodin, S.; Krencker, F. N.; Kothe, T.; Hoffmann, R.; Mattioli, E.; Heimhofer, U.; Kabiri, L. (2016). "Perturbation of the carbon cycle during the late Pliensbachian–early Toarcian: New insight from high-resolution carbon isotope records in Morocco". Journal of African Earth Sciences. 116 (2): 89–104. Bibcode:2016JAfES.116...89B. doi:10.1016/j.jafrearsci.2015.12.018.
- ^ Beauchamp, W. (2004). "Superposed folding resulting from inversion of a synrift accommodation zone, Atlas Mountains, Morocco". AAPG Memoir. 82 (82): 635–646. Retrieved 25 January 2022.
- ^ Manspeizer, W. (1988). Triassic–Jurassic rifting, Continental Breakup and the Origin of the Atlantic Ocean and Passive Margins. Amsterdam: Elsevier. pp. 41–79. ISBN 978-0-444-42903-2. Retrieved 22 August 2022.
- ^ Font, E.; Youbi, N.; Fernandes, S.; El Hachimi, H.; Kratinova, Z.; Hamim, Y. (2011). "Revisiting the magnetostratigraphy of the Central Atlantic Magmatic Province from Morocco". Earth and Planetary Science Letters. 309 (4): 302–317. doi:10.1016/j.epsl.2011.07.007.
- ^ Teixell, A.; Arboleya, M. L.; Julivert, M.; Charroud, M. (2003). "Tectonic shortening and topography in the central High Atlas (Morocco)". Tectonics. 22 (5): 6–14. Bibcode:2003Tecto..22.1051T. doi:10.1029/2002TC001460. S2CID 55571408. Retrieved 25 January 2022.
- ^ Ibouh, H.; El Bchari, F.; Bouabdelli, M.; Souhel, A.; Youbi, N. (2001). "L'accident tizal-azourki haut atlas central du maroc: déformations synsedimentaires liasiques en extension et conséquences du serrage atlasique". Estudios Geológicos. 57 (2): 15–30. doi:10.3989/egeol.01571-2124. Retrieved 25 January 2022.
- ^ Duval-Arnould, A.; Schröder, S.; Charton, R.; Joussiaume, R.; Razin, P.; Redfern, J. (2021). "Early post-rift depositional systems of the Central Atlantic: Lower and Middle Jurassic of the Essaouira-Agadir Basin, Morocco" (PDF). Journal of African Earth Sciences. 178 (1): 104–164. Bibcode:2021JAfES.17804164D. doi:10.1016/j.jafrearsci.2021.104164. S2CID 233818813.
- ^ a b Malaval, Manon (2016-09-09). Enregistrement sédimentaire de l'activité diapirique associée à la ride du Jbel Azourki, Haut Atlas central, Maroc : impact sur la géométrie des dépôts et la distribution des faciès des systèmes carbonatés et mixtes du Jurassique inférieur (These de doctorat thesis). Bordeaux 3.
- ^ a b c d e Ettaki, M.; Ibouh, H.; Chellaï, E. H. (2007). "Événements tectono-sédimentaires au Lias-Dogger de la frange méridionale du Haut-Atlas central, Maroc". Estudios Geológicos. 63 (2): 103–125. Retrieved 2 February 2022.
- ^ Ibouh, H.; El Bchari, F.; Bouabdelli, M.; Souhel, A.; Youbi, N. (2001). "L'accident tizal-azourki haut atlas central du maroc: déformations synsedimentaires liasiques en extension et conséquences du serrage atlasique". Estudios Geológicos. 57 (2): 15–30. doi:10.3989/egeol.01571-2124. Retrieved 25 January 2022.
- ^ Andrieu, S.; Krencker, F. N.; Bodin, S. (2022). "Anatomy of a platform margin during a carbonate factory collapse: implications for the sedimentary record and sequence stratigraphy interpretation of poisoning events". Journal of the Geological Society. 179 (5): 15–75. Bibcode:2022JGSoc.179....5A. doi:10.1144/jgs2022-005. Retrieved 25 January 2022.
- ^ a b c d e f Montenat, C.; Monbaron, M.; Allain, R.; Aquesbi, N.; Dejax, J.; Hernandez, J.; Taquet, P. (2005). "Stratigraphie et paléoenvironnement des dépôts volcano-détritiques à dinosauriens du Jurassique inférieur de Toundoute (Province de Ouarzazate, Haut-Atlas–Maroc)" (PDF). Eclogae Geologicae Helvetiae. 98 (2): 261–270. Bibcode:2005SwJG...98..261M. doi:10.1007/s00015-005-1161-x. S2CID 129577717. Retrieved January 25, 2022.
- ^ a b c d e f g h i j k l m n o p q r s t Souhel, A. (1996). "Le Mésozoïque dans Haut Atlas de Beni-Mellal (Maroc). Stratigraphie, sédimentologie et évolution géodynamique" (PDF). Strata: Série 2, Mémoires. 27 (6): 1–227. Retrieved 12 May 2022.
- ^ Bassoullet, J. P.; Elmi, S.; Poisson, A.; Cecca, F.; Bellion, Y.; Guiraud, R.; Vrielynck, B. (1993). "Middle Toarcian". Atlas Tethys Paleoenvironmental Maps. 7 (1): 63–84.
- ^ a b c d e f g h Krencker, F. N.; Fantasia, A.; Danisch, J.; Martindale, R.; Kabiri, L.; El Ouali, M.; Bodin, S. (2020). "Two-phased Collapse of the Shallow-water Carbonate Factory during the Late Pliensbachian–Toarcian Driven by Changing Climate and Enhanced Continental Weathering in the Northwestern Gondwana Margin". Earth-Science Reviews. 208 (1): 103–254. Bibcode:2020ESRv..20803254K. doi:10.1016/j.earscirev.2020.103254. S2CID 225669068.
- ^ Kairouani, Hajar; Abbassi, Anas; Zaghloul, Mohamed Najib; El Mourabet, Mohamed; Micheletti, Francesca; Fornelli, Annamaria; Mongelli, Giovanni; Critelli, Salvatore (2024). "The Jurassic climate change in the northwest Gondwana (External Rif, Morocco): Evidence from geochemistry and implication for paleoclimate evolution". Marine and Petroleum Geology. 163: 106762. Bibcode:2024MarPG.16306762K. doi:10.1016/j.marpetgeo.2024.106762. ISSN 0264-8172. S2CID 267956440.
- ^ Lang, J.; Mahdoudi, M.L.; Pascal, A. (1990). "Sedimentation-calcrete cycles in the Mesozoic Red formations from the central High atlas (Telouet area), Morocco". Palaeogeography, Palaeoclimatology, Palaeoecology. 81 (1–2): 79–93. Bibcode:1990PPP....81...79L. doi:10.1016/0031-0182(90)90041-5. ISSN 0031-0182.
- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z Brame, H. M. R.; Martindale, R. C.; Ettinger, N. P.; Debeljak, I.; Vasseur, R.; Lathuilière, B.; Bodin, S. (2019). "Stratigraphic distribution and paleoecological significance of Early Jurassic (Pliensbachian-Toarcian) lithiotid-coral reefal deposits from the Central High Atlas of Morocco". Palaeogeography, Palaeoclimatology, Palaeoecology. 514 (2): 813–837. Bibcode:2019PPP...514..813B. doi:10.1016/j.palaeo.2018.09.001.
- ^ Bodin, S.; Mattioli, E.; Frohlich, S.; Marshall, J.D.; Boutib, L.; Lahsini, S.; Redfern, J. (2010). "Toarcian carbon isotope shifts and nutrient changes from the Northern margin of Gondwana (High Atlas, Morocco, Jurassic): palaeoenvironmental implications" (PDF). Palaeogeogr. Palaeoclimatol. Palaeoecol. 297 (1): 377–390. Bibcode:2010PPP...297..377B. doi:10.1016/j.palaeo.2010.08.018. S2CID 128495419.
- ^ Krencker, François-Nicolas; Bodin, Stéphane; Suan, Guillaume; Heimhofer, Ulrich; Kabiri, Lahcen; Immenhauser, Adrian (2015). "Toarcian extreme warmth led to tropical cyclone intensification". Earth and Planetary Science Letters. 425: 120–130. doi:10.1016/j.epsl.2015.06.003. ISSN 0012-821X.
- ^ a b c d Krencker, F. N.; Bodin, S.; Hoffmann, R.; Suan, G.; Mattioli, E.; Kabiri, L.; Immenhauser, A. (2014). "The middle Toarcian cold snap: trigger of mass extinction and carbonate factory demise". Global and Planetary Change. 117 (1): 64–78. Bibcode:2014GPC...117...64K. doi:10.1016/j.gloplacha.2014.03.008. Retrieved 25 January 2022.
- ^ Moragas, Mar; Baqués, Vinyet; Travé, Anna; Martín-Martín, Juan Diego; Saura, Eduard; Messager, Gregoire; Hunt, David; Vergés, Jaume (2019-07-10). "Diagenetic evolution of lower Jurassic platform carbonates flanking the Tazoult salt wall (Central High Atlas, Morocco)". Basin Research. 32 (3): 546–566. doi:10.1111/bre.12382. hdl:10261/186591. ISSN 0950-091X.
- ^ Martín-Martín, J. D.; Vergés, J.; Saura, E.; Moragas, M.; Messager, G.; Baqués, V.; Razin, P.; Grélaud, C.; Malaval, M.; Joussiaume, R.; Casciello, E.; Cruz-Orosa, I.; Hunt, D. W. (2017). "Diapiric growth within an Early Jurassic rift basin: The Tazoult salt wall (central High Atlas, Morocco)". Tectonics. 36 (1): 2–32. Bibcode:2017Tecto..36....2M. doi:10.1002/2016tc004300. hdl:10261/142474. ISSN 0278-7407.
- ^ a b c Pierre, A.; Durlet, C.; Razin, P.; Chellai, E. H. (2010). "Spatial and temporal distribution of ooids along a Jurassic carbonate ramp: Amellago outcrop transect, High-Atlas, Morocco". Geological Society, London, Special Publications. 329 (1): 65–88. Bibcode:2010GSLSP.329...65P. doi:10.1144/sp329.4. ISSN 0305-8719.
- ^ a b c d e f g Fonville, Tanner; Martindale, Rowan C.; N. Stone, Travis; Septfontaine, Michel; Bodin, Stéphane; Krencker, François-Nicolas; Kabiri, Lahcen (2024). "Early Jurassic Benthic Foraminiferal Ecology From The Central High Atlas Mountains, Morocco". PALAIOS. 39 (8): 277–299. Bibcode:2024Palai..39..277F. doi:10.2110/palo.2023.026.
- ^ a b c d e f g Fadile, A. (2003). "Carte géologique du Maroc au 1/100 000, feuille d'Imilchil". Notes et Mémoires du Service géologique du Maroc. 397.
- ^ Löwner, Ralf (2009). "Recherches sedimentologiques et structurales à l'articulation entre Haut et Moyen Atlas et la Haute Moulouya, Maroc". Publications of the Universität Berlin. 356 (2): 2–212. doi:10.14279/DEPOSITONCE-2264. S2CID 132486463.
- ^ a b c d e f g h i j k l m Khaffou, H.; Hssaida, T.; Maatouf, W.; Essafraoui, B.; El Ouali, M.; Essamoud, R.; Louaya, A.; Rachid, J.; Chakir, S.; Jaydawi, S.; Chafai, K. (2023). "Le Toarcien (sommet de la Zone à Polymorphum–Zone à Bonarelli) d'Amellagou (Haut Atlas Central, Maroc) : Palynostratigraphie et Paléoenvironnement" (PDF). Bulletin de l'Institut Scientifique, Rabat, Section Sciences de la Terre. 45 (6): 111–130.
- ^ Boudchiche, L.; Sadki, D. (2000). "Mise en évidence de la limite Pliensbachien-Toarcien par les ammonites, les foraminifères et l'interaction tectono-eustatique dans la région de Todrha-Dadès". Revenue de paléobiologie. 19: 299–317. Retrieved 8 September 2021.
- ^ Chafiki, D. (1994). "Dynamique sédimentaire à l'articulation plate forme-bassin: Exemple du Lias de la région de Beni Melal (Haut Atlas central-Maroc)". Thèse de 3ième cycle, Université Cadi Ayyad, Marrakech. 1 (1): 189p. S2CID 130402988.
- ^ Chafiki, D.; ElHariri, K.; Souhel, A.; Lachkar, N.; Sarih, S.; Dommergues, J.L.; Garcia, J.P.; Quiquerez, A. (2007). "Données lithostratigraphiques et biostratigraphiques sur le Lias dans le cadre de deux transects du Haut-Atlas central (Beni Mellal et Midelt-Errachidia, Maroc)". Africa Geoscience Review. 14 (1): 15–28. Retrieved 8 September 2021.
- ^ a b c d e f Rodríguez-Tovar, F. J. (2021). "Ichnology of the Toarcian Oceanic Anoxic Event: An understimated tool to assess palaeoenvironmental interpretations". Earth-Science Reviews. 216 (1): 103–119. Bibcode:2021ESRv..21603579R. doi:10.1016/j.earscirev.2021.103579. S2CID 233849558.
- ^ a b c d Benzaggagh, Mohamed; Salamon, Mariusz A.; Khaffou, Hanane; Hssaida, Touria; El Ouali, Mohamed; Essafraoui, Badre (2022). "Brachiopodes toarciens de la coupe d'Aït Athmane, Haut Atlas centro-oriental (Maroc)". Annales de Paléontologie. 108 (4): 102572. Bibcode:2022AnPal.10802572B. doi:10.1016/j.annpal.2022.102572. ISSN 0753-3969.
- ^ a b c d Alméras, Y.; Fauré, P.; Cougnon, M. (2017). "Brachiopodes toarciens du Haut-Atlas central (Maroc). Implications biostratigraphiques et paléobiogéographiques". Bulletin de la Société d'histoire naturelle de Toulouse. 153 (5): 47–66.
- ^ Lucienne, Rousselle (1973). "Le genre de Pseudogibbirhynchia : Rhynchonellacea : dans le Toarcien et l'Aalenien inferieur du Haut Atlas central et oriental". Notes du Service géologique du Maroc. 34 (254): 121–133.
- ^ a b Jenny, J. (1988). "Carte géologique du Maroc au 1/100 000: feuille Azilal (Haut Atlas central). Mémoire explicatif". Notes et Mémoires du Service géologique. 378 (1): 1–122. Retrieved 25 January 2022.
- ^ a b Dubar, G. (1948). "Etudes paléontologiques sur le lias du Maroc: La faune domérienne du Jebel Bou-Dahar, près de Béni-Tajjite: Bivalvia" (PDF). Notes et mémoires du Service géologique du Maroc. 68 (2): 147–2011.
- ^ a b c Jossen, Jean-Arsène (1990). "Carte géologique du Maroc 1:100 000, Zawyat Ahançal". Editions du Service Géologique du Maroc.
- ^ Posenato, R.; Crippa, G. (2023). "An insight into the systematics of Plicatostylidae (Bivalvia), with a description of Pachygervillia anguillaensis n. gen. n. sp. from the Lithiotis Facies (Lower Jurassic) of Italy". Riv. It. Paleontol. Strat. 129 (3): 551–572. Retrieved 13 November 2023.
- ^ a b c Dubar, G. (1948). "Etudes paléontologiques sur le lias du Maroc: La faune domérienne du Jebel Bou-Dahar, près de Béni-Tajjite: Gastropoda" (PDF). Notes et mémoires du Service géologique du Maroc. 68 (2): 40–144.
- ^ a b c d e f g h i Benzaggagh, Mohamed; Khaffou, Hanane; Salamon, Mariusz A.; Hssaida, Touria; Ouali, Mohamed El; Essafraoui, Badre (2022). "Ammonites du Toarcien du Haut Atlas central (Maroc)". Annales de Paléontologie. 108 (2): 102540. Bibcode:2022AnPal.10802540B. doi:10.1016/j.annpal.2022.102540. ISSN 0753-3969.
- ^ a b El Bchari, F.; Souhel, A. (2008-10-27). "Jurassic (uppermost Sinemurian - Aalenian) sequence stratigraphy and geodynamic evolution of the Ait Bou Guemmez area (Central High Atlas, Morocco)". Estudios Geológicos. 64 (2). doi:10.3989/egeol.08642.028. ISSN 1988-3250.
- ^ Krencker, François-Nicolas; Lindström, Sofie; Bodin, Stéphane (2019-08-29). "A major sea-level drop briefly precedes the Toarcian oceanic anoxic event: implication for Early Jurassic climate and carbon cycle". Scientific Reports. 9 (1): 12518. doi:10.1038/s41598-019-48956-x. ISSN 2045-2322. PMC 6715628. PMID 31467345.
- ^ Termier, H. (1942). "Données nouvelles sur le Jurassique rouge à Dinosauriens du Grand et du Moyen-Atlas (Maroc) [New data on the Jurassic red beds with dinosaurs from the Great and Middle Atlas (Morocco)]". Bulletin de la Société Géologique de France. 12 (6): 199–207. doi:10.2113/gssgfbull.S5-XII.4-6.199. Retrieved 25 January 2022.
- ^ a b c d Allain, R.; Tykoski, R.; Aquesbi, N.; Jalil, N. E.; Monbaron, M.; Russell, D.; Taquet, P. (2007). "An abelisauroid (Dinosauria: Theropoda) from the Early Jurassic of the High Atlas Mountains, Morocco, and the radiation of ceratosaurs" (PDF). Journal of Vertebrate Paleontology. 27 (3): 610–624. doi:10.1671/0272-4634(2007)27[610:AADTFT]2.0.CO;2. S2CID 131617581.
- ^ Ibrahim, N.; Sereno, P. C.; Zouhri, S.; Zouhri, S. (2017). "Les dinosaures du Maroc–aperçu historique et travaux récents" (PDF). Mémoires de la Société Géologique de France. 180 (4): 249–284. Retrieved 21 April 2023.
- ^ a b c d Jenny, J.; Jenny-Deshusses, C.; Le Marrec, A.; Taquet, P. (1980). "Découverte d'ossements de Dinosauriens dans le Jurassique inférieur (Toarcien) du Haut Atlas central (Maroc) [Discovery of dinosaur bones in the Lower Jurassic (Toarcian) of the central High Atlas (Morocco)]". Comptes Rendus de l'Académie des Sciences, Série D. 290 (1): 839–842. Retrieved 25 January 2022.
- ^ a b c Taquet, P. (1985). "Two new Jurassic specimens of coelurosaurs (Dinosauria)". The beginning of birds. Eichstätt, Germany: Freunde des Jura Museums. 1 (1): 229–232.
- ^ a b c d Taquet, P. (2010). "The dinosaurs of Maghreb: the history of their discovery". Historical Biology. 22 (3): 88–99. Bibcode:2010HBio...22...88T. doi:10.1080/08912961003625657. S2CID 85069400.
- ^ Allain, Ronan; Bailleul, Alida (2010). "First Revision of the Theropod from the Toarcian of Wazazant (High Atlas Mountains, Morocco): The oldest Know Tetanureae?". Abstracts du 1er Congrès International sur la Paléontologie des Vertébrés du Nord de l'Afrique. 1 (1): 34.
- ^ Benson, Roger B. J. (2010). "The osteology of Magnosaurus nethercombensis (Dinosauria, Theropoda) from the Bajocian (Middle Jurassic) of the United Kingdom and a re-examination of the oldest records of tetanurans". Journal of Systematic Palaeontology. 8 (1): 131–146. Bibcode:2010JSPal...8..131B. doi:10.1080/14772011003603515. S2CID 140198723.
- ^ Mortimer, M. "RE:African Kakuru-like material". Dinosaur Mailing List. Cleveland Museum of Natural History. Retrieved 25 January 2022.
- ^ a b c d Termier, H. (1942). "Données nouvelles sur le Jurassique rouge à Dinosauriens du Grand et du Moyen-Atlas (Maroc) [New data on the Jurassic red beds with dinosaurs from the Great and Middle Atlas (Morocco)]". Bulletin de la Société Géologique de France. 12 (6): 199–207. doi:10.2113/gssgfbull.S5-XII.4-6.199. Retrieved 25 January 2022.
- ^ a b Allain, R. (2012). Histoire des dinosaures. Paris: Perrin. p. 112. ISBN 978-2081353053. Retrieved 25 January 2022.
- ^ Taquet, P. (1986). "Les découvertes récentes de dinosaures au Maroc. In Les dinosaures de la Chine à la France". Colloque international de paléontologie. 7 (2): 39–43.
- ^ a b Peyer, K.; Allain, R. (2010). "A reconstruction of Tazoudasaurus naimi (Dinosauria, Sauropoda) from the late Early Jurassic of Morocco". Historical Biology. 22 (3): 134–141. Bibcode:2010HBio...22..134P. doi:10.1080/08912960903562317. S2CID 140569817. Retrieved 25 January 2022.
- ^ a b Allain, R.; Aquesbi, N. (2008). "Anatomy and phylogenetic relationships of Tazoudasaurus naimi (Dinosauria, Sauropoda) from the late Early Jurassic of Morocco". Geodiversitas. 30 (2): 345–424. Retrieved 25 January 2022.
- ^ Lévêque, P. (1961). "Contribution à l'étude géologique et hydrogéologique de l'Atlas de Demnate (Maroc)". Thèse Sciences.
- ^ Allain, Ronan; Aquesbi, Najat; Jean, Dejax; Meyer, Christian; Monbaron, Michel; Montenat, Christian; Richir, Philippe; Rochdy, Mohammed; Russell, Dale; Taquet, Philippe (2004). "A basal sauropod dinosaur from the Early Jurassic of Morocco" (PDF). Comptes Rendus Palevol. 3 (3): 199–208. Bibcode:2004CRPal...3..199A. doi:10.1016/j.crpv.2004.03.001.
- ^ Gandini, Jacques. "Tazouda (Toundoute) - Les fouilles". prehistoire-du-maroc. Le Marroc Avant l´historie. Retrieved 19 July 2022.
- ^ Löwner, R. (2009). "Recherches sedimentologiques et structurales à l'articulation entre Haut et Moyen Atlas et la Haute Moulouya, Maroc" (PDF). Publications of the Universität Berlin. 356 (2): 2–212. Retrieved 20 August 2022.
- ^ Allain, Ronan; Aquesbi, Najat; Jean, Dejax; Meyer, Christian; Monbaron, Michel; Montenat, Christian; Richir, Philippe; Rochdy, Mohammed; Russell, Dale; Taquet, Philippe (2004). "A basal sauropod dinosaur from the Early Jurassic of Morocco" (PDF). Comptes Rendus Palevol. 3 (3): 199–208. Bibcode:2004CRPal...3..199A. doi:10.1016/j.crpv.2004.03.001.
- ^ Ghandour, I. M.; Fürsich, F. T. (2022). "Allogenic and autogenic controls on facies and stratigraphic architecture of the Lower Jurassic Mashabba Formation, Gebel Al-Maghara, North Sinai, Egypt". Proceedings of the Geologists' Association. 133 (1): 67–86. Bibcode:2022PrGA..133...67G. doi:10.1016/j.pgeola.2021.12.001. S2CID 245403051.
- ^ Louz, E.; Rais, J.; Barka, A. A.; Nadem, S.; Barakat, A. (2022). "Geological heritage of the Taguelft syncline (M'Goun Geopark): Inventory, assessment, and promotion for geotourism development (central high atlas, Morocco)". International Journal of Geoheritage and Parks. 10 (2): 218–239. Bibcode:2022IJGP...10..218L. doi:10.1016/j.ijgeop.2022.04.002. S2CID 248279651.
- ^ Gazeau, F. (1969). "Sur quelques structures de bois Mésozoïques du Maroc". Notes, Mém. Serv. Géol. Maroc. 210 (3): 93–120.
- ^ Philippe, M.; Bamford, M.; McLoughlin, S.; Alves, L. S. R.; Falcon-Lang, H. J.; Gnaedinger, S.; Zamuner, A. (2004). "Biogeographic analysis of Jurassic–Early Cretaceous wood assemblages from Gondwana". Review of Palaeobotany and Palynology. 129 (3): 141–173. Bibcode:2004RPaPa.129..141P. doi:10.1016/j.revpalbo.2004.01.005.
- ^ Gazeau, F. (1969). "Etude du Protophyllocladoxylon maurianum Gazeau 1967 du Jurassique du Haut Atlas". Notes et Mémoires du Service Géologique du Maroc. 210 (3): 108–113.